Continuous modeling of creased annuli with tunable bistable and looping behaviors

TL;DR

This paper introduces a continuous geometric model for creased annuli, enabling analysis of their bistability and shape-shifting behaviors, with potential applications in deployable and morphable structures.

Contribution

It develops a smooth, continuous description of creases using RDDF, facilitating nonlinear mechanics analysis of creased annuli with complex behaviors.

Findings

Creased annuli exhibit generic bistability and can adopt various shapes.

The model shows excellent agreement with physical and finite element models.

Dynamic switching between states is achievable by varying rest curvature.

Abstract

Creases are purposely introduced to thin structures for designing deployable origami, artistic geometries, and functional structures with tunable nonlinear mechanics. Modeling the mechanics of creased structures is challenging because creases introduce geometric discontinuity and often have complex mechanical responses due to the local material damage. In this work, we propose a continuous description of the sharp geometry of creases and apply it to the study of \emph{creased annuli}, made by introducing radial creases to annular strips with the creases annealed to behave elastically. We find creased annuli have generic bistability and can be folded into various compact shapes, depending on the crease pattern and the overcurvature of the flat annulus. We use a regularized Dirac delta function (RDDF) to describe the geometry of a crease, with the finite spike of the RDDF capturing the localized curvature. Together with anisotropic rod theory, we solve the nonlinear mechanics of creased annuli, with its stability determined by the standard conjugate point test. We find excellent agreement between precision tabletop models, numerical predictions from our analytical framework, and modeling results from finite element simulations. We further show that by varying the rest curvature of the thin strip, dynamic switches between different states of creased annuli can be achieved, which could inspire the design of novel deployable and morphable structures. We believe our smooth description of discontinuous geometries will benefit to the mechanical modeling and design of a wide spectrum of engineering structures that embrace geometric and material discontinuities.